Liquid crystal panel

ABSTRACT

A liquid crystal panel ( 10 ) includes a plurality of pixels arranged in a matrix pattern having rows and columns. A plurality of Cs bus lines ( 43   c ) as storage capacitor lines are routed in the row direction of the liquid crystal panel ( 10 ). A plurality of branch lines ( 310 ) are routed in the column direction across a pixel region ( 10   a ). The branch lines ( 310 ) are connected to the Cs bus lines ( 43 c) so that control signals are sent to storage capacitors from the branch lines ( 310 ) through the Cs bus lines ( 43   c ).

TECHNICAL FIELD

The present invention relates to a liquid crystal panel in which aplurality of pixels are arranged in a matrix pattern having rows andcolumns. Note that this application claims priority under the ParisConvention or laws and regulations of destination countries to JapanesePatent Application No. 2009-123630 filed on May 21, 2009. The content ofthe basic application is incorporated herein by reference.

BACKGROUND ART

As such a liquid crystal panel, the present inventors have proposed whatis known as multi-pixel driving (referred to also as “area coveragemodulation display”, “area coverage modulation driving” or “multi-pixeldisplay”) techniques in, for example, WO2006/098449 (InternationalPublication WO06/098449 pamphlet (Patent Document 1)), etc.

In such a liquid crystal panel, a plurality of pixels are arranged in amatrix pattern having rows and columns. With this technique, twosubordinate pixels for making the effective voltages to be applied tothe liquid crystal layer different from each other are provided withinone pixel. A different storage capacitor is provided for eachsubordinate pixel. A vibration voltage is applied to the storagecapacitor. With such multi-pixel driving, brightness/darkness isdetermined for each subordinate pixel by inverting the polarity of thevoltage supplied to the storage capacitor.

In this case, the storage capacitors of the subordinate pixels areconnected to a plurality of storage capacitor lines (referred to also as“Cs bus lines”, etc.) routed in the row direction, for example. Thestorage capacitor lines are connected to stem lines (referred to also as“Cs stem lines”) routed on both sides in the row direction. Then,control signals are sent to the storage capacitors through the stemlines and the storage capacitor lines.

The publication states that waveform rounding (rounding of waveforms)occurs, due to electric resistance, etc., for control signals of thestorage capacitors (e.g., WO2006/098449, Paragraphs 0120-0121). For theproblem of the waveform rounding, the publication discloses that it isimproved by increasing the vibration frequency of the control signalsgiven to the storage capacitor lines.

Citation List Patent Document

Patent Document 1: International Publication WO06/098449 pamphlet

SUMMARY OF THE INVENTION Technical Problem

Now, the screen size of a liquid crystal display device has beenincreased in applications such as displays for TV sets. As the screensize increases, the length of the wiring path to the storage capacitorsdescribed above increases. Thus, the phenomenon of waveform roundingdescribed above is also likely to occur. For applications such asdisplays for TV sets, the front surface of the panel is surrounded by abezel-like frame. In order to achieve a smaller display width for thesame screen size, there is a demand for reducing the width of thebezel-like frame (demand for thinning the bezel). One method forreducing the phenomenon of waveform rounding described above is tothicken the stem lines provided on both sides in the row direction ofthe liquid crystal panel so as to reduce the resistance of the stemlines. However, thickening the stem lines contradicts the demand forthinning the bezel. When the stem lines are thinned in order to addressthe demand for thinning the bezel, the resistance in the wiring path tothe storage capacitors increases, and it is more likely that thephenomenon of waveform rounding occurs. In view of this, the presentinvention proposes a novel structure for lines for sending controlsignals to storage capacitors of the liquid crystal display device.

Solution to the Problem

A liquid crystal panel of the present invention includes a plurality ofpixels arranged in a matrix pattern having rows and columns. A storagecapacitor is provided in each pixel. A plurality of storage capacitorlines are routed in the row direction and connected to the storagecapacitors arranged in the row direction. A plurality of branch linesare routed in the column direction across a pixel region where theplurality of pixels are arranged. The branch lines are connected to acontrol signal supply section for sending control signals to the storagecapacitors from the branch lines through the storage capacitor lines.With this liquid crystal panel, it is not always necessary to providestem lines in opposite edge portions in the row direction, and evenwhere stem lines are provided, the stem lines can be made thinner.Therefore, it is possible to reduce the space in the opposite edgeportions in the row direction of the liquid crystal panel (thin thebezel). A plurality of branch lines can be provided across the pixelregion. Therefore, it is possible to shorten the wiring path to eachstorage capacitor and to suppress the resistance of the wiring path tothe storage capacitor to be low. Thus, it is possible to improve the“waveform rounding” of the control signal of the storage capacitor. Notethat the term “branch line” as used herein is defined based on thedescription of the present specification.

In this case, the liquid crystal panel may include a plurality of stemlines routed in at least one edge portion in the row direction, with thestorage capacitor lines connected to the stem lines. In this case, it ispreferred that the stem lines are connected to the control signal supplysection, and control signals are sent to the storage capacitors from thestem lines through the storage capacitor lines. The liquid crystal panelmay include a plurality of horizontal stem lines routed in an edgeportion in the column direction, with the branch lines connected to thehorizontal stem lines.

The plurality of branch lines may be grouped into a plurality of groups,and may be connected to the control signal supply section so that thesame control signal is sent to branch lines belonging to the same group.In this case, it is preferred that the plurality of storage capacitorlines are each connected to branch lines belonging to one group. In thiscase, the liquid crystal panel may include a plurality of stem linesrouted in at least one edge portion in the row direction. It ispreferred that each storage capacitor line is connected to one of theplurality of stem lines; and the same control signal as the controlsignal sent to the branch lines belonging to one group to which thestorage capacitor line is connected is sent to the stem line by thecontrol signal supply section. Moreover, the liquid crystal panel mayinclude a plurality of horizontal stem lines routed in an edge portionin the column direction. In this case, it is preferred that the branchlines belonging to one group are connected to one horizontal stem linethat is different from horizontal stem lines to which branch lines ofother groups are connected.

The branch lines may be routed evenly across different pixels. Forexample, where each pixel includes R, G and B sub-pixels, the branchlines may be routed so as to pass through R sub-pixels of the R, G and Bsub-pixels. The branch lines may be routed so as to pass through Gsub-pixels of the R, G and B sub-pixels. The branch lines may be routedso as to pass through B sub-pixels of the R, G and B sub-pixels.

The liquid crystal panel may include: a liquid crystal layer; a pair ofsubstrates with the liquid crystal layer interposed therebetween; acounter electrode formed on one of the pair of substrates; and a pixelelectrode formed on the other substrate opposing the counter electrode.In this case, two branch lines that receive a pair of control signalswhose signal voltage changes are of opposite directions and of an equalamount may be routed so as to pass through an area where the pixelelectrode is formed. Thus, the influences of the capacitances(capacitive couplings) formed between the branch lines and the pixelelectrode are canceled out between the two branch lines, and it ispossible to reduce the influence from the capacitances formed betweenthe branch lines and the pixel electrode.

In a case where a plurality of branch lines are routed so as to passthrough an area where the pixel electrode of the pixel is formed,capacitances (capacitive couplings) formed between the branch lines andthe pixel electrode may be made equal to each other. Thus, if theplurality of branch lines receive a pair of control signals whose signalvoltage changes are of opposite directions and of an equal amount, thereis a significant effect of canceling out the influences of thecapacitances (capacitive couplings) formed between the branch lines andthe pixel electrode. A largest value of a plurality of capacitancesformed between the branch lines and the pixel electrode may be less thanor equal to twice a smallest value thereof. Also in this case, if theplurality of branch lines receive a pair of control signals whose signalvoltage changes are of opposite directions and of an equal amount, theinfluences of the capacitances (capacitive couplings) formed between thebranch lines and the pixel electrode are canceled out, thereby reducingthe influence from the capacitances (capacitive couplings) formedbetween the branch lines and the pixel electrode. Note that morepreferably, the largest value of the plurality of capacitances is lessthan or equal to 1.5 times the smallest value thereof.

Where a plurality of branch lines are routed so as to pass through anarea where the pixel electrode of the pixel is formed, areas over whichthe branch lines as projected onto the pixel electrode overlap the pixelelectrode may be made equal to each other. For example, it is preferredthat the areas over which the branch lines overlap the pixel electrodeas viewed in a plan view of the substrate on which the pixel electrodeis formed are equal between the plurality of branch lines. Thus, if theplurality of branch lines receive a pair of control signals whose signalvoltage changes are of opposite directions and of an equal amount, thereis a significant effect of canceling out the influences of thecapacitances (capacitive couplings) formed between the branch lines andthe pixel electrode. A plurality of branch lines may be routed so as topass through an area where the pixel electrode of the pixel is formed;and a largest value of areas over which the branch lines as projectedonto the pixel electrode overlap the pixel electrode may be less than orequal to twice a smallest value thereof. Also in this case, if theplurality of branch lines receive a pair of control signals whose signalvoltage changes are of opposite directions and of an equal amount, theinfluences of the capacitances (capacitive couplings) formed between thebranch lines and the pixel electrode are canceled out, thereby reducingthe influence from the capacitances (capacitive couplings) formedbetween the branch lines and the pixel electrode. Note that morepreferably, the largest value of the areas over which the branch linesas projected onto the pixel electrode overlap the pixel electrode isless than or equal to 1.5 times the smallest value thereof.

As a different embodiment, the branch lines are routed so as to passthrough an area where the pixel electrode of the pixel is formed; andCx/(Clc+Cs+Cx)≦0.2 holds, where Clc is a capacitance formed by thecounter electrode and the pixel electrode, Cs is a capacitance of thestorage capacitor, and Cx is a capacitance formed between the branchline and the pixel electrode. In this case, it is possible to relativelyreduce the influence due to the capacitance formed between the branchline and the pixel electrode to such a degree that there is no problemin teens of the display quality. Note that where the branch lines arerouted so as to pass through an area where the pixel electrode of thepixel is formed, it is preferred that Cx/(Clc+Cs+Cx)≦0.2 holds for eachof the capacitances Cx formed between the branch lines and the pixelelectrode.

A gap may be formed between the pixel electrodes and the branch line maybe routed so as to pass through the gap between the pixel electrodes. Inthis case, it is possible to suppress the occurrence of the capacitivecoupling.

Each pixel may include subordinate pixels having different brightnesslevels. In this case, it is preferred that the subordinate pixels havingdifferent brightness levels include storage capacitors connected todifferent storage capacitor lines. It is preferred that the storagecapacitors provided in the subordinate pixels having differentbrightness levels receive a pair of control signals whose signal voltagechanges are of opposite directions and of an equal amount through thedifferent storage capacitor lines.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 A vertical cross-sectional view of a liquid crystal displaydevice.

FIG. 2 A plan view showing an array substrate of a liquid crystal panel.

FIG. 3 A plan view showing a color filter substrate of a liquid crystalpanel.

FIG. 4 A plan view showing a sub-pixel of a liquid crystal panel.

FIG. 5 A diagram showing a circuit configuration of a sub-pixel of aliquid crystal panel.

FIG. 6 A diagram showing a wiring structure of storage capacitor linesof a liquid crystal panel.

FIG. 7 A control block diagram of a liquid crystal panel.

FIG. 8 A diagram showing a circuit configuration of a sub-pixel of aliquid crystal panel.

FIG. 9 A diagram showing a change in a charge of a pixel electrode.

FIG. 10 A diagram showing a change in a charge of a pixel electrode.

FIG. 11 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 12 A diagram showing waveform rounding occurring in a controlsignal.

FIG. 13 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 14 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 15 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 16 A plan view showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 17 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 18 A diagram showing an equivalent circuit of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 19 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 20 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 21 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 22 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 23 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 24 A diagram showing an equivalent circuit of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 25 A diagram showing an equivalent circuit of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 26 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 27 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 28 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 29 A diagram showing a circuit configuration of a liquid crystalpanel according to an embodiment of the present invention.

FIG. 30 A diagram showing ripples occurring on a storage capacitor line.

DESCRIPTION OF EMBODIMENTS

A liquid crystal panel according to an embodiment of the presentinvention will now be described with reference to the drawings.

As shown in FIG. 13, a liquid crystal panel 10 includes a plurality ofbranch lines 310 routed in the column direction across a pixel region 10a in which a plurality of Cs bus lines 43 c (storage capacitor lines)are routed in the row direction. The branch lines 310 are connected tothe Cs bus lines 43 c so that control signals are sent to the storagecapacitors from the branch lines 310 through the Cs bus lines 43 c. Bythus forming a plurality of wiring paths for sending the control signalsc from the branch lines 310 to the storage capacitors Cs through the Csbus lines 43 c, the resistance of a wiring path for sending the controlsignal c to the storage capacitor Cs is reduced, and the “waveformrounding” of the control signal c sent to the storage capacitor Cs issuppressed to be small. With the liquid crystal panel 10, it is possibleto thin the bezel of the liquid crystal display device. The details ofthe liquid crystal panel 10 will now be described.

Here, first, a structure of a liquid crystal display device having aliquid crystal panel 10 where the branch lines 310 are not formed (seeFIG. 11) will be described schematically, and the “waveform rounding”occurring on the Cs bus line 43 c (storage capacitor line) will bedescribed. Then, a liquid crystal display device (see FIG. 13) where thebranch lines 310 are formed will be described, and how the “waveformrounding” is improved and how the bezel is thinned will be described.Note that the configuration of the liquid crystal display deviceillustrated herein is merely an example, and the specific configurationof the liquid crystal display device is not limited to the followingembodiment. The drawings do not necessarily reflect the configuration ofan actual product. Members or portions serving substantially the samefunction are denoted by the same reference numerals as appropriate.Numbers and characters in parentheses attached to the same referencenumeral are used for the distinction between a plurality of members orportions serving the same function,

FIG. 1 schematically shows a cross-sectional configuration of a liquidcrystal display device 100. The liquid crystal display device 100includes the liquid crystal panel 10 and a backlight 20 as shown inFIG. 1. The liquid crystal panel 10 generally has a rectangular shape asa whole, and is formed by a pair of light-transmissive substrates 11 and12 (glass substrates). In this embodiment, the front side one of thesubstrates 11 and 12 is a color filter substrate 11 (CF substrate), andthe rear side one is an array substrate 12 (TFT substrate).

In this embodiment, as shown in FIG. 1, the color filter substrate 11and the array substrate 12 each have the pixel region 10 a. Herein, thepixel region 10 a is a region where pixels are formed, and is referredto also as a display region. The color filter substrate 11 and the arraysubstrate 12 are arranged so as to oppose each other. A sealant 15 isprovided between the color filter substrate 11 and the array substrate12 so as to surround the pixel region 10 a along its periphery (outerperipheral portion) in the circumferential direction.

A liquid crystal layer 13 is provided between the color filter substrate11 and the array substrate 12. The liquid crystal layer 13 includes aliquid crystal material including liquid crystal molecules. As a voltageis applied between the color filter substrate 11 and the array substrate12, the alignment direction of the liquid crystal molecules is operatedto change the optical characteristics of the liquid crystal material.The sealant 15 seals the liquid crystal material of the liquid crystallayer 13.

The array substrate 12 and the color filter substrate 11 will now bedescribed in this order. FIGS. 2 and 3 show the pixel region 10 a of theliquid crystal panel 10 on an enlarged scale. FIG. 2 shows a plan viewof a pixel region portion of the array substrate 12, and FIG. 3 shows aplan view of a pixel region portion of the color filter substrate 11.The region surrounded by broken line A in FIGS. 2 and 3 denotes a regionforming one pixel of the liquid crystal panel 10. The liquid crystalpanel 10 includes pixels A shown in FIGS. 2 and 3 arranged in a matrixpattern having rows and columns. FIG. 4 is a plan view showing onesub-pixel A_(R) of the pixel A on an enlarged scale. FIG. 5 is a circuitdiagram showing a configuration of the sub-pixel A_(R), A_(G), A_(B) ofthe pixel A. Note that FIG. 5 shows a circuit configuration of onesub-pixel located at i^(th) row and j^(th) column (i,j) of the liquidcrystal panel 10.

In this embodiment, the array substrate 12 includes pixel electrodes 42a and 42 b, bus lines 43 a to 43 c (bus lines), an alignment film 46(vertical alignment film), and thin film transistors 47 a and 47 b(TFTs) formed on the front side (the liquid crystal layer 13 side) of aglass substrate as shown in FIGS. 2 and 4. The pixel electrodes 42 a and42 b are made of ITO (indium tin oxide) which is a transparentconductive material. Voltages according to the image are supplied tothese pixel electrodes 42 a and 42 b at a predetermined timing via thebus lines 43 a to 43 c and the thin film transistors 47 a and 47 b (seeFIG. 2). The pixel electrodes 42 a and 42 b and the bus lines 43 a to 43c (see FIG. 2) are routed with an insulating layer interposed. Thealignment film 46 made of polyimide, or the like, is formed on the arraysubstrate 12. A rubbing treatment is performed on the surface of thealignment film 46 so as to determine the alignment direction of theliquid crystal molecules in the absence of an applied voltage. In thisembodiment, the array substrate 12 includes the storage capacitors Cs.The structure of the storage capacitors Cs will later be described indetail.

The color filter substrate 11 includes a black matrix 52, color filters53, a counter electrode 55 and an alignment film 56 (vertical alignmentfilm) formed on the rear side (the liquid crystal layer 13 side) of aglass substrate as shown in FIG. 3. The black matrix 52 is formed by ametal such as Cr (chromium) so that light does not pass through a regionbetween pixels. There are three colors of color filters 53, i.e., red(R), green (C) and blue (B). One of the red (R), green (C) and blue (B)color filters opposes one of the R, G and B pixel electrodes 42 a and 42b of the array substrate 12 as shown in FIGS. 2 and 3. The counterelectrode 55 made of ITO (indium tin oxide) is formed under the blackmatrix 52 and the color filter 53 (the side opposing the array substrate12). An alignment film (not shown) is formed under the counter electrode55. A rubbing treatment is performed also on the surface of thisalignment film (not shown).

Moreover, spherical or columnar spacers (not shown) are interposedbetween the color filter substrate 11 and the array substrate 12. Thespacers are for example formed by plastic, glass, or the like. The gapbetween the color filter substrate 11 and the array substrate 12 is heldby the sealant 15 described above and the spacers, thereby maintainingthe gap of the liquid crystal layer 13.

As shown in FIG. 1, polarizer plates 17 and 18 are attached to the frontside of the color filter substrate 11 and the rear side of the arraysubstrate 12, respectively. This embodiment is directed to a liquidcrystal panel in which the alignment films 46 and 56 are formed byvertical alignment films as described above (a liquid crystal panel of aso-called vertical alignment mode). With a liquid crystal panel of thevertical alignment mode, the polarization axes of the two polarizerplates 17 and 18 are orthogonal to each other. In this embodiment, abezel 30 is attached to the front side of the liquid crystal panel 10 asshown in FIG. 1. A frame 32 is attached to the rear side of the liquidcrystal panel 10. The bezel 30 and the frame 32 support the liquidcrystal panel 10. Moreover, the frame 32 supports the periphery aroundan area corresponding to the pixel region 10 a of the liquid crystalpanel 10. The frame 32 has an opening across the area corresponding tothe pixel region 10 a of the liquid crystal panel 10. The backlight 20of the liquid crystal display device 100 is attached to the rear side ofthe liquid crystal panel 10.

As shown in FIG. 1, the backlight 20 is an external light sourcearranged on the rear side (the right side in FIG. 1) of the liquidcrystal panel 10. In this embodiment, the backlight 20 includes aplurality of light sources 22 (e.g., a cold cathode tube, light emittingdiodes (LEDs), etc.) and a backlight chassis 24. The backlight chassis24 has a box shape with an opening facing the front side (the liquidcrystal panel 10 side). A plurality of light sources 22 are arranged inthe backlight chassis 24. A plurality of optical sheets 26 are arrangedso as to be stacked together in the opening of the backlight chassis 24.

The optical sheet 26 includes, for example, a diffuser plate, a diffusersheet, a lens sheet and a luminance enhancing sheet in this order fromthe rear side. The backlight chassis 24 is attached to the rear side ofthe frame 32 with the light sources 22 facing the liquid crystal panel10 described above. Then, the optical sheet 26 is interposed between therear surface of the frame 32 of the liquid crystal panel 10 and thefront surface of the backlight chassis 24. The liquid crystal displaydevice 100 includes a control section 200 as shown in FIG. 1. Thecontrol section 200 includes a circuit (e.g., a light modulating circuitsuch as a cold cathode tube inverter circuit) for adjusting theluminance (brightness) of the backlight 20 according to the image orvideo to be displayed. The control section 200 adjusts the brightness ofthe backlight 20 by for example adjusting the power to be input to thelight sources 22,

A controlled voltage is applied to the color filter substrate 11 and thearray substrate 12 of the liquid crystal panel 10. This operates theliquid crystal molecules in the liquid crystal layer 13 of the liquidcrystal panel 10. With the liquid crystal panel 10, the liquid crystalmolecules in the liquid crystal layer 13 are operated for each of thepixels A (more specifically the sub-pixels A_(R), A_(G) and A_(B)defined by R, G and B). Thus, light from the backlight 20 can be blockedor transmitted, and the transmittance thereof can also be changed, foreach pixel A (more specifically, each of the sub-pixels A_(R), A_(G) andA_(B) defined by R, G and B). Moreover, the liquid crystal displaydevice 100 displays an intended image while controlling the luminance ofthe backlight 20, etc. Note that each of the sub-pixels A_(R), A_(G) andA_(B) defined by R, G and B is further divided into two subordinatepixels Pa and Pb in this embodiment as shown in FIG. 2.

The driving circuit of the liquid crystal panel 10 will now bedescribed.

As shown in FIG. 5, in the array substrate 12, the bus line 43 a is asource bus line (data signal line) for sending a control signal (datasignal) to a source electrode 121 of the thin film transistors 47 a and47 b. The bus line 43 b is a gate bus line (scanning signal line) forsending a control signal (scanning signal) to a gate electrode 122 ofthe thin film transistors 47 a and 47 b. The bus line 43 c is a bus line(Cs bus line, storage capacitor line) for sending a control signal tothe storage capacitors Cs.

In this embodiment, the source bus lines 43 a are routed along thecolumn direction of the liquid crystal panel 10 as shown in FIG. 2. Thesource bus lines 43 a are arranged so as to run vertically beside thesub-pixels A_(R), A_(G) and A_(B) defined by R, G and B. In thisembodiment, the gate bus lines 43 b are routed along the row directionof the liquid crystal panel 10. The gate bus lines 43 b are arranged soas to run horizontally in the central portions of the sub-pixels A_(R),A_(G) and A_(B). The Cs bus lines 43 c are routed along the rowdirection of the liquid crystal panel 10. The Cs bus lines 43 c arearranged so as to run horizontally through the intervals of thesub-pixels A_(R), A_(G) and A_(B) in the column direction. The sourcebus lines 43 a are connected to the source driver 71. The gate bus lines43 b are connected to the gate driver 72. The Cs bus lines 43 c areconnected to a group of stem lines 180 (see FIG. 5, FIG. 6) routed onboth sides in the row direction of the liquid crystal panel 10.

In this embodiment, in each of the sub-pixels A_(R), A_(G) and A_(B),the thin film transistors 47 a and 47 b (TFTs) are provided at theintersection between the source bus line 43 a and the gate bus line 43 bas shown in FIGS. 4 and 5. The thin film transistors 47 a and 47 binclude the source electrode 121, the gate electrode 122 and drainelectrodes 123 a and 123 b. In this embodiment, the source electrode 121extends from the source bus line 43 a to the position where the thinfilm transistors 47 a and 47 b are provided. The source electrode 121 isshared by the upper and lower thin film transistors 47 a and 47 b. Thegate electrode 122 is provided in the gate bus line 43 b. The drainelectrodes 123 a and 123 b are provided in the areas of the upper andlower subordinate pixels 42 a and 42 b, respectively. A semiconductor(not shown) is present between the source electrode 121, the gateelectrode 122 and the drain electrodes 123 a and 123 b.

The subordinate pixels Pa and Pb each include the storage capacitor Cs.In the embodiment shown in FIG. 4, the storage capacitor Cs includes theCs bus line 43 c and a storage capacitor electrode 142 a or 142 bopposing the Cs bus line 43 c with an insulating film (not shown)interposed therebetween. In this embodiment, the storage capacitorelectrodes 142 a and 142 b are connected to the drain electrodes 123 aand 123 b of the thin film transistors 47 a and 47 b by lead lines 144 aand 144 b, respectively. The storage capacitor electrodes 142 a and 142b are connected to the pixel electrodes 42 a and 42 b of the subordinatepixels Pa and Pb through contact holes 142 a 1 and 142 b 1 runningthrough an interlayer insulating film (not shown).

The Cs bus lines 43 c are connected to the group of stem lines 180 alongwhich a plurality of stem lines 181 to 184 are routed. Note that thegroup of stem lines 180 collectively refers to the plurality of stemlines 181 to 184 which are routed together. The group of stem lines 180are routed along peripheral portions of the liquid crystal panel 10(opposite side portions in the row direction of the liquid crystal panel10 in this embodiment). FIG. 6 is a diagram showing the connectionstructure of the Cs bus lines 43 c and the stem lines 181 to 184.

The Cs bus lines 43 c are routed along the row direction of the liquidcrystal panel 10 as shown in FIG. 6. The Cs bus lines 43 c are arrangedwith intervals therebetween in the column direction of the liquidcrystal panel 10. As shown in FIG. 2, the storage capacitors Cs of thesubordinate pixels Pa and Pb, each arranged in the row direction of theliquid crystal panel 10, are connected to the Cs bus lines 43 c. Incontrast, as shown in FIG. 6, the stem lines 181 to 184 are routed alongthe column direction of the liquid crystal panel 10 in opposite edgeportions in the row direction of the liquid crystal panel 10. Forexample, in the embodiment shown in FIG. 6, four stem lines 181 to 184are routed in the group of stem lines 180. In this case, ones of the Csbus lines 43 c arranged in the column direction of the liquid crystalpanel 10 that are at regular intervals of four lines in the columndirection are connected to one stem line.

In the example shown in FIG. 6, eight Cs bus lines 43 c(1)-(8) arearranged sequentially in the column direction of the liquid crystalpanel 10. In this case, ones of the Cs bus lines 43 c that are atregular intervals of four lines in the column direction of the liquidcrystal panel 10 are connected to the same one of the stem lines 181 to184. That is, the Cs bus lines 43 c(1) and 43 c(5) are connected to thestem line 181. The Cs bus lines 43 c(2) and 43 c(6) are connected to thestem line 182. The Cs bus lines 43 c(3) and 43 c(7) are connected to thestem line 183. The Cs bus lines 43 c(4) and 43 c(8) are connected to thestem line 184. Note that although not shown in the figure, the Cs buslines 43 c connected to the storage capacitors Cs provided in thesubordinate pixels Pa and Pb of the liquid crystal panel 10 arepreferably connected to different stem lines.

Note that while ones of the Cs bus lines 43 c that are at regularintervals of four lines in the column direction of the liquid crystalpanel 10 are connected to the same one of the stem lines 181 to 184 inthe example shown in FIG. 6, there are actually cases where more stemlines (e.g., 12 stem lines) are provided in the liquid crystal panel 10.Although not shown in the figure, where 12 stem lines are provided, forexample, it is preferred that ones of the Cs bus lines 43 c that are atregular intervals of 12 lines are connected to the same stem line. Notethat it is preferred that the Cs bus lines 43 c are connected topredetermined stem lines so that intended control signals are sent tothe Cs bus lines 43 c. Therefore, in a case where the liquid crystalpanel 10 has 12 stem lines, it is not always the case that ones of theCs bus lines 43 c that are at regular intervals of 12 lines areconnected to the same stem line.

FIG. 7 is a block diagram showing a driving structure of the liquidcrystal panel 10. The liquid crystal display device 100 includes thecontrol section 200 as shown in FIG. 7. The control section 200 isformed by a combination of ICs, LSIs, CPU, non-volatile memories, etc.The control section 200 performs required functions by performingvarious electronic processes in accordance with a prescribed program.The liquid crystal panel 10 is controlled by the control section 200.The control section 200 includes a signal input section 201, a timingcontrol section 202, a power supply 203, and a storage capacitor controlsection 204. Note that the control of the storage capacitor Cs (see FIG.2) is not shown in FIG. 7.

The signal input section 201 receives a plurality of control signalsfrom an external system (not shown). The control signals input from theexternal system include signals relating to the video to be displayed onthe liquid crystal panel 10. In this embodiment, control signals aresent to the source driver 71 and the gate driver 72 through the timingcontrol section 202 based on the control signals input to the signalinput section 201. Based on the plurality of control signals input fromthe external system (not shown), the timing control section 202generates control signals (the scanning signal a, the data signal b) foroperating the gate driver 72 and the source driver 71. The power supply203 supplies the operation power to various components of the liquidcrystal display device 100, and generates a common electrode voltage(Vcom) of the liquid crystal panel 10 and supplies it to the counterelectrode 55 (see FIG. 5).

The storage capacitor control section 204 produces the control signals cfor controlling the storage capacitors Cs. In this embodiment, thestorage capacitor control section 204 produces the control signals c forcontrolling the storage capacitors Cs based on the control signals a andb produced by the timing control section 202. The control signals a andb for operating the gate driver 72 and the source driver 71 and thecontrol signal c for controlling the storage capacitor Cs are suppliedto the liquid crystal panel 10 after their timings are adjusted. Notethat in this embodiment, the control signal c for controlling thestorage capacitor Cs is sent from the control section 200 to the liquidcrystal panel 10 through the source substrate where the source driver 71is placed, as shown in FIG. 7.

In this embodiment, as shown in FIG. 7, the source bus line 43 a(1) tothe source bus line 43 a(m), which are routed along the rows of thematrix of the pixels A (accurately, the R, G and B sub-pixels A_(R),A_(G) and A_(B) of the pixels A) of the liquid crystal panel 10, areconnected to the source driver 71. In response to the control signalinput from the timing control section 202, the source driver 71 selectsa reference voltage to be input to the pixels A and supplies theselected reference voltage to the pixels A, thereby controlling theangle of rotation of the liquid crystal molecules.

In response to the control signal input from the timing control section202, the gate driver 72 turns ON/OFF the thin film transistors 47 a and47 b arranged on the liquid crystal panel 10. In this embodiment, thegate driver 72 sends signals to the gate bus lines 43 b(1)-(n) on theliquid crystal panel 10. When a control signal for turning ON the thinfilm transistors 47 a and 47 b is sent to one gate bus line 43 b, thethin film transistors 47 a and 47 b of pixels that are connected to thegate bus line 43 b are turned ON by the control signal. The gate driver72 sends control signals for turning ON the thin film transistors 47 aand 47 b sequentially to the gate bus lines 43 b(1)-(n).

Control signals whose timings are adjusted are sent from the sourcedriver 71 and the gate driver 72. In this embodiment, in a period oftime for which the gate driver 72 turns ON pixels that are connected toone gate bus line 43 b, a control signal for controlling the pixelsconnected to the gate bus line 43 b is sent from the source driver 71.The period of time for which the gate driver 72 turns ON all of pixelsthat are connected to one gate bus line 43 b may be called “onehorizontal sync period”. As the gate driver 72 turns ON pixels that areconnected to one gate bus line 43 b, the thin film transistors 47 a and47 b of the pixels are ON during the one horizontal sync period. In thenext horizontal sync period, the pixels connected to the gate bus line43 b are turned OFF.

The source driver 71 sends a control signal to one of the source buslines 43 a(1)-(m) for each horizontal sync period. Thus, at the timingwhen pixels that are connected to one gate bus line 43 b are turned ON,the control signal is sent to the pixels A. Thus, with the liquidcrystal panel 10, information is sequentially written to the pixelelectrodes 42 a and 42 b row by row. Then, the gate bus lines 43b(1)-(n) are sequentially turned ON. Thus, one image displayed on theliquid crystal panel 10 is formed. Therefore, by dividing a video into aplurality of chronologically-arranged still images and chronologicallyforming the still images one by one on the liquid crystal panel 10, avideo can be displayed. Note that the period of time for which one imageis formed on the liquid crystal panel 10, i.e., the period of time forwhich the gate bus lines 43 b(1)-(n) are sequentially turned ON, may becalled a “frame period (frame time)”.

In this embodiment, as shown in FIGS. 2 and 4, one pixel A is formed bythe sub-pixels A_(R), A_(G) and A_(B) defined by R, G and B. Moreover,the sub-pixels A_(R), A_(G) and A_(B) are each divided into twosubordinate pixels Pa and Pb.

Condensers (Clc) for storing charge are formed between the pixelelectrodes 42 a and 42 b of the subordinate pixels Pa and Pb and thecounter electrode 55 on the color filter substrate 11 side opposing thepixel electrodes 42 a and 42 b with the liquid crystal layer 13interposed therebetween as shown in FIGS. 4 and 5. The storagecapacitors Cs are formed between the Cs bus lines 43 c and the storagecapacitor electrodes 142 a and 142 b. The pixel electrodes 42 a and 42 bare connected to the source bus line 43 a through the thin filmtransistors 47 a and 47 b. The Cs bus lines 43 c are connected to thestem lines 181 to 184 provided in opposite edge portions in the rowdirection of the liquid crystal panel 10. The control signal c forcontrolling the storage capacitor Cs is supplied to the stem lines 181to 184 from the storage capacitor control section 204.

As described above, the thin film transistors 47 a and 47 b are openedat an appropriate timing based on the scanning signal from the gate busline 43 b. At this timing, the data signal input to the source bus line43 a is written to the pixel electrodes 42 a and 42 b. In other words,charge is stored in the pixel electrodes 42 a and 42 b based on the datasignal input to the source bus line 43 a.

In this embodiment, the liquid crystal panel 10 is controlled byso-called “dot inversion driving”. In this case, the polarity of thedata signal input to the source bus line 43 a is inverted for every dot(for every sub-pixel in this embodiment). For example, as shown in FIG.8, when a data signal having a (+) charge is input for a sub-pixel ofthe i^(th) column, a data signal having a (−) charge is input for asub-pixel of the (i+1)^(th) column. A data signal having a (+) charge isinput to a sub-pixel of the (i+2)^(th) column. Moreover, a data signalhaving a (−) charge is input to a sub-pixel of the (i+3)^(th) column.Thus, for the same frame period, the polarity of the input data signalis inverted for every column. Although not shown in the figures, in thisembodiment, the polarities of data signals input to sub-pixels adjacentto each other in the row direction are also inverted. The polarity ofthe data signal input to the same sub-pixel is inverted for every frameperiod.

In this embodiment, a control signal made of a rectangular wave is sentto the Cs bus line 43 c after the thin film transistors 47 a and 47 bare turned OFF. Then, by the influence of the voltages applied to thestorage capacitors Cs, charges stored in the pixel electrodes 42 a and42 b of the subordinate pixels Pa and Pb are maintained. Note that inthis embodiment, as shown in FIG. 5, a pair of control signals whosesignal voltage changes are of opposite directions and of an equal amountare sent to the storage capacitors Cs of the subordinate pixels Pa andPb within the same sub-pixel. In this case, one of the subordinatepixels Pa and Pb is brighter and the other darker.

That is, a pair of control signals c(i) and c(i+1) are sent to thestorage capacitors Cs of the subordinate pixels Pa and Pb within thesub-pixel. The pair of control signals c(i) and c(i+1) are controlsignals whose signal voltage changes are of opposite directions and ofan equal amount. In the example shown in FIG. 8, a rectangular wavewhose voltage level changes with a predetermined period is supplied asthe control signal c. Here, “H” denotes the high voltage level (highlevel) of the rectangular wave and “L” denotes the low voltage level(low level) of the rectangular wave. The data signal a is sent to thesource bus line 43 a(j). The scanning signal b is sent to the gate busline 43 b(i). The control signals c(i) and c(i+1) are sent to the Cs buslines 43 c(i) and 43 c(i+1). The timings of the data signal a, thescanning signal b and the Cs bus lines 43 c(i) and 43 c(i+1) areadjusted.

Sub-pixels to which a data signal having a (+) charge is input from thesource bus line 43 a will now be described. For example, in FIG. 8, theyare the sub-pixels of the i^(th) column and the (i+2)^(th) column. FIG.9 shows the transitions of the voltages applied to the pixel electrodes42 a and 42 b for the frame period in which a data signal having a (+)charge is input from the source bus line 43 a for a sub-pixel of thei^(th) column shown in FIG. 8.

In this case, as shown in FIG. 9, in the sub-pixel, in the period t1-t2in which the thin film transistor 47 is turned ON, a (+) charge e(i) isstored in the pixel electrodes 42 a and 42 b based on the data signal.Then, after the timing t3 at which the thin film transistor 47 is turnedOFF, the charges stored in the pixel electrodes 42 a and 42 b transitionby the influence of the storage capacitors Cs.

Then, in one subordinate pixel Pa in the sub-pixel, the control signalc(i) is sent from the Cs bus line 43 c(i) to the storage capacitor Cs.The voltage level of the control signal c(i) changes to “H” after thetiming t3 at which the thin film transistor 47 a is turned OFF.Therefore, in the subordinate pixel Pa, the (+) charge e(i) stored inthe pixel electrode 42 a transitions to positive (+). Thus, thesubordinate pixel Pa becomes brighter.

In contrast, in the other subordinate pixel Pb in the sub-pixel, thecontrol signal c(i+1) is sent to the storage capacitor Cs from the Csbus line 43 c(i+1). The voltage level of the control signal c(i+1)changes to “L” after the timing t3 at which the thin film transistor 47b is turned OFF. Thus, in the subordinate pixel Pb, the (+) charge e(i)stored in the pixel electrode 42 b transitions to negative (−). Thus,the subordinate pixel Pb becomes darker.

Next, sub-pixels to which a data signal having a (−) charge is inputfrom the source bus line 43 a will be described. For example, in FIG. 8,they are the sub-pixels of the (i+1)^(th) column and the (i+3)^(th)column. FIG. 10 shows the transitions of voltages applied to the pixelelectrodes 42 a and 42 b for the frame period in which a data signalhaving a (−) charge is input from the source bus line 43 a for asub-pixel of the (i+1)^(th) column shown in FIG. 8.

In this case, as shown in FIG. 10, in the sub-pixel, in the period t1-t2in which the thin film transistor 47 is turned ON, a (−) charge e(i+1)is stored in the pixel electrodes 42 a and 42 b based on the datasignal. Then, after the timing t3 at which the thin film transistor 47is turned OFF, the charges stored in the pixel electrodes 42 a and 42 btransition by the influence of the storage capacitors Cs.

Then, in one subordinate pixel Pa in the sub-pixel, the control signalc(i+1) is sent from the Cs bus line 43 c(i+1) to the storage capacitorCs. The voltage level of the control signal c(i+1) changes to “L” afterthe timing t3 at which the thin film transistor 47 a is turned OFF.Thus, in the subordinate pixel Pa, the (−) charge e(i+1) stored in thepixel electrode 42 a transitions to negative (−). Thus, the subordinatepixel Pa becomes brighter.

In contrast, in the other subordinate pixel Pb in the sub-pixel, thecontrol signal c(i+2) is sent to the storage capacitor Cs from the Csbus line 43 c(i+2). The voltage level of the control signal c(i+2)changes to “H” after the timing t3 at which the thin film transistor 47b is turned OFF. Thus, in the subordinate pixel Pb, the (−) chargee(i+1) stored in the pixel electrode 42 b transitions to positive (+).Thus, the subordinate pixel Pb becomes darker.

As described above, in this embodiment, the sub-pixels A_(R), A_(G) andA_(B) each include subordinate pixels Pa and Pb whose brightness levelsare different from each other. The subordinate pixels Pa and Pb eachinclude a storage capacitor Cs. The storage capacitors Cs of thesubordinate pixels Pa and Pb are connected to different Cs bus lines 43c (storage capacitor lines). A pair of control signals c are sent to thestorage capacitors Cs provided in the subordinate pixels Pa and Pb whosebrightness levels are different from each other. The pair of controlsignals c sent here are control signals sent through different Cs buslines 43 c, and are signals whose signal voltage changes are of oppositedirections and of an equal amount. Thus, brightness levels of thesubordinate pixels Pa and Pb are controlled.

The Cs bus lines 43 c are each provided along the row direction of theliquid crystal panel 10. A plurality of Cs bus lines 43 c are providedin the column direction of the liquid crystal panel 10. Moreover, thestorage capacitors Cs of a series of subordinate pixels Pa and Pbprovided in the row direction are connected to the Cs bus line 43 c. Forexample, ones of the Cs bus lines 43 c that are at regular intervals ofseveral lines in the column direction of the liquid crystal panel 10 areconnected to the same one of the stem lines 181 to 184 (see FIG. 6). Thesame control signal c is sent to Cs bus lines 43 c that are connected tothe same one of the stem lines 181 to 184. Note that in order tosimplify the figure, FIG. 6 illustrates an embodiment where there arefour stem lines 181 to 184 and ones that are at regular intervals offour lines are connected to the same stem line. The liquid crystal panel10 is not limited to the embodiment. In a case where a pair of controlsignals whose signal voltage changes are of opposite directions and ofan equal amount are sent, an even number of stem lines are provided inpairs of two.

Thus, with so-called “multi-pixel driving”, for data signals, controlssignals whose polarities are inverted from each other are sent to onesof the pixels A arranged in a matrix pattern that are adjacent to eachother in the column direction. Moreover, a pair of control signals c(k)and c(k+1) whose signal voltage changes are of opposite directions andof an equal amount are sent to the storage capacitors Cs provided in thefirst subordinate pixel Pa and the second subordinate pixel Pb. The twoCs bus lines 43 c through which the pair of control signals whose signalvoltage changes are of opposite directions and of an equal amount aresent are synchronized together as a pair, and the phases of controlsignals of other pairs are slightly shifted therefrom. For example,where six pairs of control signals having the same waveform and invertedpolarities are supplied through 12 stem lines, the phases of the pairsare preferably shifted by 30 degrees so that the six pairs of controlsignals are evenly shifted from one another.

With the so-called “multi-pixel driving structure” described above, onesub-pixel includes two subordinate pixels. For example, where there is apixel defect in one subordinate pixel but there is no pixel defect inthe other subordinate pixel, it is possible to prevent the sub-pixelfrom not functioning at all. Therefore, the proportion of normal pixelsis maintained to be high. In this embodiment, the brightnesses of thesubordinate pixels Pa and Pb are different from each other. In otherwords, one (e.g., the upper subordinate pixel Pa) forms a brighterpixel, and the other (e.g., the lower subordinate pixel Pb) forms adarker pixel. In such a case, the luminance of each of the R, G and Bsub-pixels A_(R), A_(G) and A_(R) can be adjusted more finely, enrichingrepresentation such as half-tone colors. Other functions of themulti-pixel driving are also described in Patent Document 1.

With the liquid crystal display device 100 of the multi-pixel driving,rectangular waves are used as control signals for controlling storagecapacitors as described above. A phenomenon called “waveform rounding”occurs in the rectangular waves. The “waveform rounding” refers to thephenomenon in which the waveform is distorted. The “waveform rounding”phenomenon will now be described.

For example, in the embodiment described above, rectangular waves areinput. It is preferred that the same waveform of the rectangular wave ismaintained for any sub-pixel in the liquid crystal panel 10. It isbelieved that the “waveform rounding” occurs due to for example theinfluence of the resistance of the wires for sending the control signalsc of the storage capacitors Cs.

That is, as shown in FIG. 5, the storage capacitors Cs are connected tothe Cs bus lines 43 c (storage capacitor lines) routed along the rowdirection of the liquid crystal panel 10. The Cs bus lines 43 c areconnected to the stem lines 181 to 184 routed in opposite edge portionsin the row direction of the liquid crystal panel 10 as shown in FIG. 11,for example. Ones of the Cs bus lines 43 c that are at regular intervalsof several lines in the column direction of the liquid crystal panel 10are connected to the same one of the stem lines 181 to 184, and the sameone of the control signals c(1)-c(4) is sent to ones that are at regularintervals of several lines. Note that the number of the stem lines 181to 184 and the number of the Cs bus lines 43 c are simplified in FIG. 11for the purpose of illustration. For example, while a case where thereare four stem lines is illustrated, the number of stem lines is notlimited to four.

The stem lines 181 to 184 are connected to the storage capacitor controlsection 204 for sending the control signals of the storage capacitorsCs. In this case, the control signals c are sent to the storagecapacitors Cs in the liquid crystal panel 10 from the storage capacitorcontrol section 204 through the stem lines 181 to 184 and the Cs buslines 43 c. In this embodiment, as shown in FIG. 7, the control signalsc are sent to the stem lines 181 to 184 from the control section 200through the substrate of the source driver 71. Therefore, the controlsignals c are sent to the stem lines 181 to 184 from the upper side ofthe liquid crystal panel 10 (the side on which the source driver 71 isprovided).

In this case, for example, it is believed that among the Cs bus lines 43c in the liquid crystal panel 10, a Cs bus line 43 c (D) placed in alower portion has a longer wiring path to the storage capacitor Cs and ahigher resistance than a Cs bus line 43 c (U) placed in an upperportion. Therefore, waveform rounding is more likely to occur on the Csbus line 43 c (D) placed in a lower potion of the liquid crystal panel10 than on the Cs bus line 43 c (U) placed in an upper portion.

FIG. 12 schematically shows the “waveform rounding”. That is, FIG. 12shows the waveform of a rectangular wave input as a control signal c forcontrolling a storage capacitor Cs. As described above, waveformrounding is more likely to occur on the Cs bus line 43 c (D) placed in alower portion of the liquid crystal panel 10 than on the Cs bus line 43c (U) placed in an upper portion. When there is waveform rounding, therising edge of the rectangular wave is blunted as shown in FIG. 12, forexample. In FIG. 12, a waveform c (U) represents the waveform of acontrol signal c supplied to the Cs bus line 43 c (U) in an upperportion of the liquid crystal panel 10. A waveform c (D) represents thewaveform of a control signal c supplied to the Cs bus line 43 c (D) in alower portion of the liquid crystal panel 10. The waveforms shownbetween the waveform c (U) and the waveform c (D) represent thewaveforms of control signals c supplied to Cs bus lines 43 c in a middleportion of the liquid crystal panel 10. Thus, the waveform of thecontrol signal c supplied to the Cs bus line 43 c tends to be moredeformed gradually from the upper portion toward the lower portion ofthe liquid crystal panel 10.

In the so-called “full high definition (Full HD)” standard, there are1920 pixels formed in the horizontal direction and 1080 pixels areformed in the vertical direction. In this case, with such a multi-pixeldriving structure as described above, the sub-pixels A_(R), A_(G) andA_(B) defined by R, G and B are formed in one pixel A, and each of thesub-pixels A_(R), A_(G) and A_(B) is further divided into twosubordinate pixels Pa and Pb. Therefore, 1920×3 subordinate pixels areformed in the horizontal direction, and 1080×2 subordinate pixels areformed in the vertical direction. Thus, as the number of pixels in thevertical direction increases, the difference in waveform roundingbetween the upper portion and the lower portion of the liquid crystalpanel 10 is likely to increase accordingly. As the number of pixels inthe horizontal direction increases, the number of storage capacitors Csconnected to a Cs bus line 43 c increases accordingly, therebyincreasing the resistance of the Cs bus line 43 c. It is believed thatif the resistance of the Cs bus line 43 c is high, the waveform roundingis more likely to occur accordingly, and the difference in waveformbetween the upper portion and the lower portion of the liquid crystalpanel 10 is likely to increase.

If the waveform of the control signal supplied to the Cs bus line 43 cof the liquid crystal panel 10 varies from one Cs bus line 43 c toanother as shown in FIG. 12 due to waveform rounding, the effect ofmulti-pixel driving may lower. If there is a Cs bus line 43 c on whichthe waveform of the control signal is significantly deformed by thewaveform rounding, streak-like non-uniformity (streaks) may occur in therow direction of the liquid crystal panel 10.

One method of reducing the waveform rounding is for example to reducethe resistance of the stem lines 181 to 184 by thickening the stem lines181 to 184 (see FIG. 11) routed in opposite edge portions in the rowdirection of the liquid crystal panel 10. However, if each of the stemlines 181 to 184 is thickened, accordingly more space is needed in theopposing edge portions of the liquid crystal panel 10. For example,consider a case where 12 stem lines are routed on both sides of theliquid crystal panel 10 in the liquid crystal panel 10 for a large TVset such as a 65-inch. In this case, it is believed that a width ofabout 1 cm is required in opposite edge portions of the liquid crystalpanel 10 as space for routing stem lines in order to obtain a sufficienteffect such that streak-like non-uniformity does not occur. Providingsuch space on both sides of the liquid crystal panel 10 contradicts thedemand for thinning the bezel.

In order to improve the problem, the present inventors conducted variousresearches and discovered a novel method for reducing waveform rounding.That is, in the present invention, as shown in FIG. 13, there are aplurality of branch lines 310 routed in the column direction across thepixel region 10 a. The branch lines 310 are connected to the Cs buslines 43 c. The control signals c of the storage capacitors Cs areproduced in the control section 200 (specifically, the storage capacitorcontrol section 204 (see FIG. 7)). In this embodiment, the controlsignals c are sent to the branch lines 310 from the control section 200(see FIG. 7) through the substrate of the source driver 71. Wiring pathsare formed along which the control signals c are sent from the branchlines 310 to the storage capacitors Cs through the Cs bus lines 43 c.

In this case, a plurality of branch lines 310 can be provided in thepixel region 10 a. By providing a plurality of branch lines 310, it ispossible to form a plurality of wiring paths along which the controlsignals c are sent from the branch lines 310 to the storage capacitorsCs through the Cs bus lines 43 c. In this case, since there are aplurality of wiring paths, the resistance of the wiring path along whichthe control signal c is sent to the storage capacitor Cs can besuppressed to be small. In this case, the more the number of branchlines 310 provided in the pixel region 10 a is increased, the more theresistance acting upon each branch line 310 can be reduced, therebygenerally reducing the resistance of the wiring paths along which thecontrol signals c are sent to the storage capacitors Cs. Therefore, ifthe number of branch lines 310 is increased, the problem of the“waveform rounding” can be improved even if each branch line 310 isthinned.

Where a plurality of branch lines 310 described above are provided inthe pixel region 10 a as shown in FIG. 13, wiring paths are formed alongwhich the control signals c are sent from the branch lines 310 to thestorage capacitors Cs through the Cs bus lines 43 c. Therefore, it ispossible to suppress the problem of the “waveform rounding” even if thestem lines 181 to 184 are thinned. Since the control signals c can besent from the branch lines 310 to the storage capacitors Cs through theCs bus lines 43 c, it is possible to suppress the problem of the“waveform rounding” even if the stem lines 181 to 184 which are routedin opposite edge portions in the row direction of the liquid crystalpanel 10 are eliminated. The stem lines 181 to 184 may be routed only inone edge portion in the row direction of the liquid crystal panel 10.

In this case, as shown in FIG. 14, a plurality of horizontal stem lines320 may be provided routed in an edge portion in the column direction ofthe liquid crystal panel 10. In this embodiment, the horizontal stemlines 320 are routed along the row direction in an upper edge portion(an edge portion in the column direction) of the liquid crystal panel10, and the branch lines 310 are connected to the horizontal stem lines320. With the horizontal stem lines 320, the branch lines 310 areelectrically connected, and the wiring paths of control signals to thestorage capacitors Cs are made more uniform, thereby reducing thedifference between waveforms due to waveform rounding. Thus, it ispossible to suppress the problem of the “waveform rounding”. In thiscase, although space is needed for routing a plurality of horizontalstem lines 320 in an edge portion in the column direction of the liquidcrystal panel 10, the horizontal stem lines 320 are wires for connectingthe branch lines 310 and do not need to be thick and space for routingthe plurality of horizontal stem lines 320 does not require a largewidth. For example, where 12 horizontal stem lines 320 are routed in theliquid crystal panel 10 for a large TV set such as a 65-inch full highdefinition standard, necessary horizontal stem lines 320 can be routedif there is a width of about 1 to 3 mm in an edge portion in the columndirection of the liquid crystal panel 10.

Next, the connection between the branch lines 310 and the Cs bus lines43 c will be described. For example, as shown in FIG. 6, a plurality ofCs bus lines 43 c are provided in the column direction of the liquidcrystal panel 10. The control signal of the same storage capacitor Cs issent to ones of the Cs bus lines 43 c that are at regular intervals ofseveral lines. That is, in the example shown in FIG. 6, four stem lines181 to 184 are routed in opposite edge portions in the row direction ofthe liquid crystal panel 10. Ones of the Cs bus lines 43 c routed in thecolumn direction that are at regular intervals of four lines areconnected to the same stem line. Thus, the same control signal issupplied to ones of the Cs bus lines 43 c routed in the column directionthat are at regular intervals of four lines.

Thus, there are cases where ones of the Cs bus lines 43 c that are atregular intervals of several lines receive the same control signal. Inthis case, the plurality of branch lines 310 routed across the pixelregion 10 a are preferably grouped into a plurality of groups. Then,they are preferably connected to the storage capacitor control section204 so that the same control signal is sent to branch lines belonging tothe same group. Moreover, one Cs bus line 43 c is preferably connectedto branch lines 310 belonging to one group. Thus, it is possible tosupply one control signal to one Cs bus line 43 c.

Where the same control signal is supplied to ones of the Cs bus lines 43c that are at regular intervals of four lines, the plurality of branchlines 310 routed across the pixel region 10 a are preferably groupedinto four groups I-IV as shown in FIG. 15. Then, the branch lines 310are preferably connected to the storage capacitor control section 204(see FIG. 14) so that the same control signal is sent to the branchlines 310 belonging to the same group. Ones of the Cs bus lines 43 cthat are at regular intervals of four lines are preferably connected tothe branch lines 310 belonging to the same group. Thus, the same controlsignal is supplied to the Cs bus line 43 c from a plurality of branchlines 310 belonging to the same group. Then, it is possible to give thesame control signal to the storage capacitors Cs connected to the Cs busline 43 c.

Where the liquid crystal panel 10 includes a plurality of stem lines 181to 184 in edge portions in the row direction as shown in FIGS. 14 and15, a Cs bus line 43 c is preferably connected to one of the pluralityof stem lines 181 to 184. Then, the same control signal as that sent tothe branch lines 310 belonging to one group to which the Cs bus line 43c is connected is preferably sent to the one stem line by the storagecapacitor control section 204 (see FIG. 14).

In this embodiment, as shown in FIGS. 14 and 15, the liquid crystalpanel 10 includes a plurality of horizontal stem lines 320 routed in anedge portion in the column direction (an upper edge portion in theillustrated example). Branch lines 310 belonging to one group areconnected to one horizontal stem line 320 that is different fromhorizontal stem lines 320 connected with branch lines 310 of the othergroups. In this case, since the branch lines 310 belonging to one groupto which the same control signal is sent by the storage capacitorcontrol section 204 are electrically connected through the horizontalstem lines 320, it is possible to reduce the waveform rounding on thebranch lines 310.

Where the branch lines 310 are routed across the pixel region 10 a, thebranch lines 310 may be routed through the pixels A of the liquidcrystal panel 10 as shown in FIGS. 16 and 17. In this case, it ispreferred that the branch lines 310 are routed evenly for differentpixels A. Thus, the pixels A can be configured evenly, and it ispossible to prevent display non-uniformity from one pixel A to another.

For example, where each pixel A of the liquid crystal panel 10 includesR, G and B sub-pixels as shown in FIGS. 16 and 17, the branch lines 310are routed so as to pass through the R sub-pixels A_(R) of the R, G andB sub-pixels, Thus, where the branch lines 310 are routed through the Rsub-pixels A_(R), it is preferred that the branch lines 310 are routedso as to evenly pass through the R sub-pixels A_(R) for all the pixels Aof the liquid crystal panel 10. Thus, the pixels A can be configuredevenly, and it is possible to prevent display non-uniformity from onepixel A to another.

Although not shown in the figures, the branch lines 310 may be routed soas to pass through the G sub-pixels A_(G). The branch lines 310 may berouted so as to pass through the B sub-pixels A_(B). Also in this case,by evenly configuring the pixels A, it is possible to prevent displaynon-uniformity from one pixel A to another. For example, the branchlines 310 may be provided through all of the sub-pixels A_(R), A_(G) andA_(B) of the R, G and B sub-pixels. The branch lines 310 may be providedthrough sub-pixels of two colors selected from the R, G and B sub-pixelsA_(R), A_(G) and A_(B).

One of the sub-pixels A_(R), A_(G) and A_(B) through which the branchline 310 is routed is preferably selected taking into consideration thecharacteristics, etc., of the pixels A for the liquid crystal panel 10.For example, a sub-pixel that has a small influence on the transmittanceof the pixel as a whole may be selected in order to prevent a decreasein the transmittance of the pixel A as a whole. For example, where thesub-pixel A_(G) of the sub-pixels A_(R), A_(G) and A_(B) has a highcontribution to the transmittance of the pixel A as a whole, the othersub-pixels A_(R) and A_(B) which have small influence on thetransmittance of the pixel as a whole are preferably selected assub-pixels through which the branch lines 310 are passed. For example,the sub-pixel through which the branch line 310 is passed may beselected taking into consideration the influence on the hue of the colordisplayed by the pixel as a whole.

For example, if the sub-pixel A_(B) of the sub-pixels A_(R), A_(G) andA_(B) has the smallest influence on the optical transmittance for thepixel A as a whole, the branch line 310 may be passed through thesub-pixels A_(B) so as to suppress the influence on the opticaltransmittance for the pixel A as a whole to be small. Where thesub-pixel A_(R) of the sub-pixels A_(R), A_(G) and A_(B) has thesmallest influence on the hue of the pixel A as a whole, the branch line310 may be passed through the sub-pixels A_(R) so as to suppress theinfluence on the hue of the pixel A as a whole to be small. Similarly,where it is appropriate to pass the branch line 310 through thesub-pixel A_(G) of the sub-pixels A_(R), A_(G) and A_(B), the branchline 310 is preferably passed through the sub-pixel A_(G). Note that thehue of the pixel A can be solved through adjustment with the color ofthe backlight 20. For example, where the pixel A as a whole grows bluishas the branch line 310 is passed through the sub-pixel A_(R), abacklight emitting slightly yellowish light can be selected so as tosolve the problem, thus adjusting the hue of the pixel A as a whole.Conversely, which color of sub-pixels the branch lines 310 should bepassed through may be selected based on the hue of the backlight to beemployed.

Depending on the configuration of the liquid crystal panel 10, theconfiguration of the pixel A may not be such a configuration of the R, Gand B sub-pixels A_(R), A_(G) and A_(B) as shown in FIGS. 2 and 3. Insuch a case, the branch lines 310 are preferably routed so as to passthrough appropriate ones of a plurality of sub-pixels. The branch lines310 are preferably formed in the pixel region 10 a, and may be forexample routed along the source bus lines 43 a so as not to interferewith the source bus lines 43 a. Thus, they may be routed in portions ofthe array substrate 12 excluding openings (areas through which lightpasses). The branch lines 310 may be routed so as to pass through areaswhere the pixel electrodes 42 a and 42 b are formed.

Note that FIG. 18 shows an equivalent circuit in a case where the branchlines 310 are formed so as to pass through areas where the pixelelectrodes 42 a and 42 b are formed. In this case, as shown in FIG. 18,capacitive couplings Cx(1)-Cx(2) may be formed between the pixelelectrodes 42 a and 42 b of the subordinate pixels Pa and Pb and thebranch line 310. In this case, the capacitive couplings Cx may vary thevoltages of the pixel electrodes 42 a and 42 b depending on the controlsignals c(k) and c(k+1) supplied to the branch lines 310. Here, controlsignals c that are different from the control signals c supplied tostorage capacitors Cc provided in the subordinate pixels Pa and Pb maybe sent to the branch lines 310 routed so as to oppose the pixelelectrodes 42 a and 42 b. For example, in the subordinate pixel Pb inthe equivalent circuit shown in FIG. 18, the control signal c(k+1) sentto the storage capacitor Cs is different from the control signal c(k)supplied to the branch line 310 routed so as to pass through the areawhere the pixel electrode 42 b of the subordinate pixel Pb is formed. Inthis case, in the subordinate pixel Pb, the voltage of the pixelelectrode 42 b is influenced by the capacitive coupling Cx(2). Since theinfluence of the capacitive coupling Cx is not even across all thepixels A, it produces a display non-uniformity, thus causing problems interms of the display quality.

In this case, each of the subordinate pixels Pa and Pb is preferablyconfigured so that Cx/(Clc+Cs+Cx)≦0.2 holds, where Clc is thecapacitance formed by the counter electrode 55 and the pixel electrode42 a or 42 b, Cs is the capacitance of the storage capacitor Cs, and Cxis the capacitance formed between the branch line 310 and the pixelelectrode 42 a or 42 b, as shown in FIG. 18. With such a configurationthat Cx/(Clc+Cs+Cx)≦0.2 holds, for the subordinate pixel Pa or Pb as awhole, the capacitive coupling Cx is not relatively very large ascompared with the capacitance Clc formed by the counter electrode 55 andthe pixel electrode 42 a or 42 b and the storage capacitance Cs.Therefore, it is possible to prevent a display non-uniformity from beingperceived when the liquid crystal panel 10 is observed by human eyes,and to prevent problems in terms of the display quality.

FIGS. 19 to 21 show embodiments where the branch lines 310 are routedthrough areas where the pixel electrodes 42 a and 42 b are formed asdescribed above. In the embodiment shown in FIG. 19, one source bus line43 a is routed for every pair of subordinate pixels Pa and Pb. Thestorage capacitors Cs are formed generally in central portions of theareas in which the pixel electrodes 42 a and 42 b of the subordinatepixels Pa and Pb are formed. In this embodiment, the storage capacitorCs includes an electrode 143 connected to the Cs bus line 43 c and thestorage capacitor electrode 142 a or 142 b opposing each other with aninsulating layer interposed therebetween. The storage capacitorelectrodes 142 a and 142 b are connected to the drain electrodes of thethin film transistors 47 a and 47 b by lead lines 144 a and 144 b,respectively. The electrodes 143 opposing the storage capacitorelectrodes 142 a and 142 b are connected to the Cs bus lines 43 c bylead lines 146. The electrodes 143 opposing the storage capacitorelectrodes 142 a and 142 b are formed respectively in conductor layers148 a and 148 b routed in the row direction. The branch line 310 isconnected to the Cs bus line 43 c through a contact hole 160. In thisembodiment, the branch line 310 is routed so as to pass through thesub-pixel A_(R) of the R, G and B sub-pixels A_(R), A_(G) and A_(B).

FIG. 20 shows an embodiment similar to that of FIG. 19 except that twosource bus lines 43 a are routed for every pair of subordinate pixels Paand Pb. In this case, the thin film transistors 47 a and 47 b may beprovided so that the gate electrodes 122 face each other in adjacentsubordinate pixels Pa and Pb. FIG. 21 shows an embodiment where theposition where the branch line 310 is routed is brought closer to oneedge portion of the pixel electrodes 42 a and 42 b. In this case, asshown in FIG. 18, the configuration is such that Cx/(Clc+Cs+Cx)≦0.2holds by the unit of the subordinate pixels Pa and Pb. Then, even if thebranch lines 310 are routed so as to pass through the areas where thepixel electrodes 42 a and 42 b are formed, it is possible to preventproblems in terms of the display quality due to the influence of thecapacitive coupling Cx.

As shown in FIGS. 22 and 23, a gap s1 may be formed between the pixelelectrodes 42 a and 42 b and the branch line 310 may be routed so as topass through the gap s1. An equivalent circuit in this case is as shownin FIG. 24. In this case, as shown in FIG. 24, the branch line 310 isrouted through the gap s1 formed between the pixel electrodes 42 a and42 b. Therefore, the capacitive coupling Cx is not formed, and there areno problems in terms of the display quality due to the influence of thecapacitive coupling Cx.

For example, with the multi-pixel driving, one sub-pixel is formed bytwo subordinate pixels as shown in FIGS. 5 and 8. One of the twosubordinate pixels becomes brighter as the control signal of the storagecapacitor Cs changes from the high level to the low level. The othersubordinate pixel becomes darker as the control signal of the storagecapacitor Cs changes from the low level to the high level. Therefore,with the multi-pixel driving, as shown in FIGS. 5 and 8, a pair ofcontrol signals whose signal voltage changes are of opposite directionsand of an equal amount are sent to two subordinate pixels forming onesub-pixel.

In this case, two branch lines 310 are routed so as to pass through theareas where the pixel electrodes 42 a and 42 b are formed. A pair ofcontrol signals c(k) and c(k+1) whose signal voltage changes are ofopposite directions and of an equal amount may be supplied to the twobranch lines 310. An equivalent circuit in this case is shown in FIG.25. In this case, the capacitive couplings Cx(1)-Cx(4) are formedbetween the pixel electrodes 42 a and 42 b of the subordinate pixels Paand Pb and the branch lines 310. However, a pair of control signals c(k)and c(k+1) whose signal voltage changes are of opposite directions andof an equal amount are supplied to the two branch lines 310 passingthrough the areas where the pixel electrodes 42 a and 42 b are formed.Therefore, the influences from the capacitive couplings Cx(1) and Cx(3)formed in the subordinate pixel Pa are canceled out by each other.Therefore, the influences from the capacitive couplings Cx(2) and Cx(4)formed in the subordinate pixel Pb are also canceled out by each other.Thus, even in a case where the branch lines 310 are routed so as to passthrough the areas where the pixel electrodes 42 a and 42 b of thesubordinate pixels Pa and Pb are formed, it is possible to preventproblems in terms of the display quality due to the influence of thecapacitive coupling Cx.

Note that in this case, the capacitances of the capacitive couplingsCx(1) and Cx(3) formed between the branch line 310 and the pixelelectrode 42 a may be made equal to each other. The capacitances of thecapacitive couplings Cx(2) and Cx(4) formed between the branch line 310and the pixel electrode 42 b may also be made equal to each other. Then,the effect of canceling out the influences from the capacitive couplingsCx(1)-Cx(4) is enhanced. In a case where a plurality of capacitivecouplings Cx are formed in one subordinate pixel Pa or Pb, it ispreferred that the largest value of the capacitances of the plurality ofcapacitive couplings Cx is less than or equal to twice the smallestvalue. That is, it is preferred that the largest value of thecapacitances of the capacitive couplings Cx(1) and Cx(3) is less than orequal to twice the smallest value. It is preferred that the largestvalue of the capacitances of the capacitive couplings Cx(2) and Cx(4) isless than or equal to twice the smallest value. It is more preferredthat the largest value of the plurality of capacitances is less than orequal to 1.5 times the smallest value.

In a case where a plurality of branch lines 310 are routed so as to passthrough the areas where the pixel electrodes 42 a and 42 b of thesubordinate pixels Pa and Pb are formed, areas over which the branchlines 310 as projected onto the pixel electrodes 42 a and 42 b overlapthe pixel electrodes 42 a and 42 b may be made equal to each other. Forexample, the areas over which the branch lines 310 overlap the pixelelectrodes 42 a and 42 b as viewed in a plan view of the substrate onwhich the pixel electrodes 42 a and 42 b are formed are preferably madeequal between the plurality of branch lines. Then, the capacitances ofthe plurality of capacitive couplings Cx formed by the plurality ofbranch lines 310 and the pixel electrodes 42 a and 42 b becomeapproximate to each other. Thus, the effect of canceling out theinfluences from the plurality of capacitive couplings is increased. Thelargest value of the areas over which the branch lines 310 as projectedonto the pixel electrodes 42 a and 42 b overlap the pixel electrodes 42a and 42 b is preferably less than or equal to twice the smallest value.In this case, more preferably, the largest value of the areas over whichthe branch lines 310 as projected onto the pixel electrodes 42 a and 42b overlap the pixel electrodes 42 a and 42 b is less than or equal to1.5 times the smallest value. Thus, as the areas over which the branchlines 310 overlap the pixel electrodes 42 a and 42 b as viewed in a planview of the substrate on which the pixel electrodes 42 a and 42 b areformed are closer to each other among the plurality of branch lines, thecapacitances of the plurality of capacitive couplings Cx are moreapproximate to each other, thereby increasing the effect of cancelingout the influences from the plurality of capacitive couplings.

In this case, FIGS. 26 to 29 each show a multi-pixel driving embodimentin which two branch lines 310 a and 310 b that receive a pair of controlsignals whose signal voltage changes are of opposite directions and ofan equal amount are routed so as to pass through the areas where thepixel electrodes 42 a and 42 b of the subordinate pixels Pa and Pb areformed.

As described above, as shown in FIG. 13, a plurality of branch lines 310are routed along the column direction across the pixel region 10 a wherea plurality of Cs bus lines 43 c (storage capacitor lines) are routedalong the row direction. The branch lines 310 are connected to the Csbus lines 43 c so that control signals are sent to the storagecapacitors from the branch lines 310 through the Cs bus lines 43 c. Bythus forming a plurality of wiring paths for sending the control signalsc from the branch lines 310 to the storage capacitors Cs through the Csbus lines 43 c, the resistance of a wiring path for sending the controlsignal c to the storage capacitor Cs can be reduced, and the “waveformrounding” of the control signal c sent to the storage capacitor Cs canbe suppressed to be small.

Now, the branch lines 310 also have an effect of reducing a ripple Vcs1occurring on the Cs bus line 43 c. That is, as shown in FIGS. 5 and 30,in the liquid crystal panel 10, one electrode of the storage capacitorCs is formed by a portion of the pixel electrode 42 a or 42 b. Arequired voltage is applied to the pixel electrodes 42 a and 42 b of thepixel A from the source driver 71 through the source bus line 43 a atthe timing ΔT at which the thin film transistor 47 is turned ON by ascanning signal SG. When a required voltage is applied to the pixelelectrodes 42 a and 42 b, the ripple Vcs1 may occur on the Cs bus line43 c connected to the pixel electrode 42 via the storage capacitor Cs.

The ripple Vcs1 may remain on the Cs bus line 43 c without attenuatingeven after the thin film transistor 47 is turned OFF. If the ripple Vcs1remains on the Cs bus line 43 c without attenuating even after the thinfilm transistor 47 is turned OFF, it may influence the voltages appliedto the condensers Clc for operating the liquid crystal layer 13 of aplurality of pixels A connected to the Cs bus line 43 c. With the liquidcrystal panel 10 described above, however, Cs bus lines 43 c areconnected to other Cs bus lines 43 c by the branch lines 310. Therefore,the ripple Vcs1 occurring on a Cs bus line 43 c diffuses to other Cs buslines 43 c through the branch lines 310 and therefore attenuatesquickly. Thus, the disturbance of an image due to the ripple Vcs1 isreduced. Thus, by the provision of the branch lines 310, the liquidcrystal panel 10 can reduce the disturbance of an image due to theripple Vcs1.

While the liquid crystal display device according to one embodiment ofthe present invention has been described above, the present invention isnot limited to the embodiment described above, and various changes canbe made thereto.

For example, the specific configuration of the liquid crystal displaydevice is not limited to the embodiment described above. Particularly,various changes can be made in, for example, how the Cs bus lines(storage capacitor lines), the stem lines, the branch lines and thehorizontal stem lines are routed or connected together. In theembodiment described above, one pixel A includes the R, G and Bsub-pixels A_(R), A_(G) and A_(B), and each of the sub-pixels A_(R),A_(G) and A_(B) further includes upper and lower subordinate pixels Paand Pb. The upper and lower subordinate pixels Pa and Pb operateindividually. Thus, in the embodiment described above, a liquid crystalpanel of a multi-pixel driving type is illustrated. The structure of theliquid crystal panel is not particularly limited to a liquid crystalpanel of a multi-pixel driving type. While a structure where a backlightis placed directly under the liquid crystal panel so as to oppose theliquid crystal panel has been illustrated as a specific configuration ofthe liquid crystal display device, a so-called edge light type may alsobe employed. The liquid crystal panel of the present invention can beused as a liquid crystal panel of a liquid crystal projector, or thelike.

DESCRIPTION OF REFERENCE CHARACTERS

-   -   10 Liquid crystal panel    -   10 a Pixel region    -   11 Color filter substrate    -   12 Array substrate    -   13 Liquid crystal layer    -   15 Sealant    -   17, 18 Polarizer plate    -   20 Backlight    -   22 Light source    -   24 Backlight chassis    -   26 Optical sheet    -   30 Bezel    -   32 Frame    -   42 Pixel electrode    -   42 a, 42 b Pixel electrode (of subordinate pixel)    -   43 a Source bus line    -   43 b Gate bus line    -   43 c Cs bus line (storage capacitor line)    -   46 Alignment film    -   47, 47 a, 47 b Thin film transistor    -   52 Black matrix    -   53 Color filter    -   55 Counter electrode    -   59 Spacer    -   71 Source driver    -   72 Gate driver    -   100 Liquid crystal display device    -   121 Source electrode    -   122 Gate electrode    -   123 a, 123 b Drain electrode    -   142 a, 142 b Storage capacitor electrode    -   144 a, 144 b Lead line    -   180 Group of stem lines    -   181-184 Stem line    -   190 Control signal supply section    -   200 Control section    -   201 Signal input section    -   202 Timing control section    -   203 Power supply    -   310 Branch line    -   320 Horizontal stem lines    -   A Pixel    -   A_(R), A_(G), A_(B) Sub-pixel    -   c Control signal of storage capacitor    -   Clc Condenser for operating liquid crystal layer    -   Cs Storage capacitor    -   e Charge    -   Pa, Pb Subordinate pixel    -   SG Scanning signal    -   Vcs1 Ripple

1.-20. (canceled)
 21. A liquid crystal panel including a plurality ofpixels arranged in a matrix pattern having rows and columns, comprising:a storage capacitor provided in each pixel; a plurality of storagecapacitor lines routed in the row direction and connected to the storagecapacitors arranged in the row direction; a plurality of branch linesrouted in the column direction across a pixel region where the pluralityof pixels are arranged; and a control signal supply section connected tothe branch lines for sending control signals to the storage capacitorsfrom the branch lines through the storage capacitor lines, wherein theliquid crystal panel includes a plurality of stem lines routed in atleast one edge portion in the row direction, with the storage capacitorlines connected to the stem lines; and the stem lines are connected tothe control signal supply section, and control signals are sent to thestorage capacitors from the stem lines through the storage capacitorlines.
 22. The liquid crystal panel according to claim 21, wherein: theliquid crystal panel includes a plurality of horizontal stem linesrouted in an edge portion in the column direction; and the branch linesare connected to the horizontal stem lines.
 23. The liquid crystal panelaccording to claim 21, wherein: the plurality of branch lines aregrouped into a plurality of groups, and are connected to the controlsignal supply section so that the same control signal is sent to branchlines belonging to the same group; and the plurality of storagecapacitor lines are each connected to branch lines belonging to onegroup.
 24. The liquid crystal panel according to claim 23, wherein: theliquid crystal panel includes a plurality of stem lines routed in atleast one edge portion in the row direction; each storage capacitor lineis connected to one of the plurality of stem lines; and the same controlsignal as the control signal sent to the branch lines belonging to onegroup to which the storage capacitor line is connected is sent to thestem line by the control signal supply section.
 25. The liquid crystalpanel according to claim 23, wherein: the liquid crystal panel includesa plurality of horizontal stem lines routed in an edge portion in thecolumn direction; and the branch lines belonging to one group areconnected to one horizontal stem line that is different from horizontalstem lines to which branch lines of other groups are connected.
 26. Theliquid crystal panel according to claim 21, wherein the branch lines arerouted evenly across different pixels.
 27. The liquid crystal panelaccording to claim 21, wherein each pixel includes R, G and Bsub-pixels, and the branch lines are routed so as to pass through Rsub-pixels of the R, G and B sub-pixels.
 28. The liquid crystal panelaccording to claim 21, wherein each pixel includes R, G and Bsub-pixels, and the branch lines are routed so as to pass through Gsub-pixels of the R, G and B sub-pixels.
 29. The liquid crystal panelaccording to 21, wherein each pixel includes R, G and B sub-pixels, andthe branch lines are routed so as to pass through B sub-pixels of the R,G and B sub-pixels.
 30. The liquid crystal panel according to claim 21,comprising: a liquid crystal layer; a pair of substrates with the liquidcrystal layer interposed therebetween; a counter electrode formed on oneof the pair of substrates; and a pixel electrode formed on the othersubstrate opposing the counter electrode, wherein two branch lines thatreceive a pair of control signals whose signal voltage changes are ofopposite directions and of an equal amount are routed so as to passthrough an area where the pixel electrode is formed.
 31. The liquidcrystal panel according to claim 21, comprising: a liquid crystal layer;a pair of substrates with the liquid crystal layer interposedtherebetween; a counter electrode formed on one of the pair ofsubstrates; and a pixel electrode formed on the other substrate opposingthe counter electrode, wherein: a plurality of branch lines are routedso as to pass through an area where the pixel electrode of the pixel isformed; and capacitances formed between the branch lines and the pixelelectrode are equal to each other.
 32. The liquid crystal panelaccording to claim 21, comprising: a liquid crystal layer; a pair ofsubstrates with the liquid crystal layer interposed therebetween; acounter electrode formed on one of the pair of substrates; and a pixelelectrode formed on the other substrate opposing the counter electrode,wherein: a plurality of branch lines are routed so as to pass through anarea where the pixel electrode of the pixel is formed; and a largestvalue of a plurality of capacitances formed between the branch lines andthe pixel electrode is less than or equal to twice a smallest valuethereof.
 33. The liquid crystal panel according to claim 21, comprising:a liquid crystal layer; a pair of substrates with the liquid crystallayer interposed therebetween; a counter electrode formed on one of thepair of substrates; and a pixel electrode formed on the other substrateopposing the counter electrode, wherein: a plurality of branch lines arerouted so as to pass through an area where the pixel electrode of thepixel is formed; and areas over which the branch lines as projected ontothe pixel electrode overlap the pixel electrode are equal to each other.34. The liquid crystal panel according to claim 21, comprising: a liquidcrystal layer; a pair of substrates with the liquid crystal layerinterposed therebetween; a counter electrode formed on one of the pairof substrates; and a pixel electrode formed on the other substrateopposing the counter electrode, wherein: a plurality of branch lines arerouted so as to pass through an area where the pixel electrode of thepixel is formed; and a largest value of areas over which the branchlines as projected onto the pixel electrode overlap the pixel electrodeis less than or equal to twice a smallest value thereof.
 35. The liquidcrystal panel according to claim 21, comprising: a liquid crystal layer;a pair of substrates with the liquid crystal layer interposedtherebetween; a counter electrode formed on one of the pair ofsubstrates; and a pixel electrode formed on the other substrate opposingthe counter electrode, wherein: the branch lines are routed so as topass through an area where the pixel electrode of the pixel is formed;and Cx/(Clc+Cs+Cx)≦0.2 holds, where Clc is a capacitance formed by thecounter electrode and the pixel electrode, Cs is a capacitance of thestorage capacitor, and Cx is a capacitance formed between the branchline and the pixel electrode.
 36. The liquid crystal panel according toclaim 21, comprising: a liquid crystal layer; a pair of substrates withthe liquid crystal layer interposed therebetween; a counter electrodeformed on one of the pair of substrates; and a pixel electrode formed onthe other substrate opposing the counter electrode, wherein a gap isformed between the pixel electrodes and the branch line is routed so asto pass through the gap.
 37. The liquid crystal panel according to claim21, wherein: each pixel includes subordinate pixels having differentbrightness levels; the subordinate pixels having different brightnesslevels include storage capacitors connected to different storagecapacitor lines; and the storage capacitors provided in the subordinatepixels having different brightness levels receive a pair of controlsignals whose signal voltage changes are of opposite directions and ofan equal amount through the different storage capacitor lines.
 38. Aliquid crystal display device comprising the liquid crystal panelaccording to claim
 21. 39. A liquid crystal TV comprising the liquidcrystal display device according to claim 38.